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JP6136074B2 - Nitrogen separation apparatus and method - Google Patents

Nitrogen separation apparatus and method Download PDF

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JP6136074B2
JP6136074B2 JP2014017510A JP2014017510A JP6136074B2 JP 6136074 B2 JP6136074 B2 JP 6136074B2 JP 2014017510 A JP2014017510 A JP 2014017510A JP 2014017510 A JP2014017510 A JP 2014017510A JP 6136074 B2 JP6136074 B2 JP 6136074B2
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戸村 啓二
啓二 戸村
林 謙年
謙年 林
雅裕 吉田
雅裕 吉田
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JFE Engineering Corp
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Description

本発明は、メタンを主成分とする原料ガスから不純物である窒素を分離して除去する窒素分離装置及び方法に関する。   The present invention relates to a nitrogen separation apparatus and method for separating and removing nitrogen, which is an impurity, from a source gas containing methane as a main component.

近年エネルギー源として、天然ガスの需要が高まっている。   In recent years, demand for natural gas has increased as an energy source.

原料ガスとしての天然ガスには、主成分のメタンの他、不純物として窒素を含む場合があり、その窒素濃度は数mol%以下のこともあれば、10mol%を超える場合もある。   Natural gas as a raw material gas may contain nitrogen as an impurity in addition to the main component methane, and the nitrogen concentration may be several mol% or less or may exceed 10 mol%.

天然ガスの利用形態として、天然ガスを液化してLNGとしてからLNGタンク内に貯め、必要に応じてLNGを再気化させてガスとして利用する場合がある。LNGタンクにおいて、外部からの入熱により不可避にボイルオフガスが発生するが、ボイルオフガスはメタンより沸点が低い窒素の濃度が高くなる傾向がある。そのため、ボイルオフガス中の窒素濃度はLNG中の窒素濃度より高く、具体的には数mol%程度のこともあるが、10mol%を超える場合もある。   As a form of use of natural gas, there is a case where natural gas is liquefied and converted into LNG and then stored in an LNG tank, and LNG is re-vaporized and used as gas as necessary. In the LNG tank, boil-off gas is inevitably generated by heat input from the outside, but the boil-off gas tends to have a higher concentration of nitrogen having a lower boiling point than methane. Therefore, the nitrogen concentration in the boil-off gas is higher than the nitrogen concentration in LNG, specifically, it may be about several mol%, but may exceed 10 mol%.

天然ガスに含まれる窒素は、燃料としての性質をもたないため、その分だけ天然ガスの発熱量を低下させるという問題がある。窒素含有量が多い場合には、燃料として求められる天然ガスの発熱量を一定の範囲内に調整するために必要な熱量増加剤(例えばLPG)の使用量が増加し、経済性が悪くなる問題がある。   Since nitrogen contained in natural gas does not have a property as a fuel, there is a problem that the calorific value of natural gas is reduced accordingly. When the nitrogen content is high, the amount of a calorific value increasing agent (for example, LPG) used to adjust the calorific value of natural gas required as a fuel within a certain range increases, resulting in poor economic efficiency. There is.

また、窒素を含む天然ガスを固体高分子型燃料電池システムに供給すると、システム内で窒素からアンモニアが生じ、生じたアンモニアが触媒毒として固体高分子型燃料電池システムに悪影響を与える問題がある。   Further, when a natural gas containing nitrogen is supplied to the solid polymer fuel cell system, ammonia is generated from the nitrogen in the system, and the generated ammonia has a problem of adversely affecting the solid polymer fuel cell system as a catalyst poison.

以上のような問題から、天然ガスなど、メタンを主成分とする原料ガスから不純物としての窒素を取り除く技術が求められている。   Due to the above problems, there is a need for a technique for removing nitrogen as an impurity from a raw material gas mainly composed of methane such as natural gas.

メタンを主成分とする原料ガスから窒素を取り除く技術として、深冷分離技術が例えば特許文献1に開示されている。深冷分離方法は、主成分と不純物との沸点差を利用して不純物を分離して除去する技術である。   For example, Patent Document 1 discloses a cryogenic separation technique as a technique for removing nitrogen from a source gas containing methane as a main component. The cryogenic separation method is a technique for separating and removing impurities by utilizing a boiling point difference between a main component and impurities.

しかし、深冷分離方法を実施するには、大がかりな設備が必要であり、一般に設備コストが高いという問題がある。特に、小規模な精製設備では一般的に経済性が悪く、処理ガス量が2万Nm/hr以下の設備では不経済になるという問題がある。 However, in order to carry out the cryogenic separation method, large-scale equipment is required, and there is a problem that equipment cost is generally high. In particular, there is a problem that a small-scale refining facility is generally not economical and a processing gas amount of 20,000 Nm 3 / hr or less is uneconomical.

次に、メタンを主成分とする原料ガスから窒素を取り除く他の技術として、圧力スイング吸着技術が例えば特許文献2に開示されている。この圧力スイング吸着技術によると、主成分よりも不純物を吸着しやすい吸着剤を収容する槽内で、圧力を昇降スイングさせて不純物を吸着剤に吸着させておいて、濃度が高くなった主成分ガスを抽出する。   Next, as another technique for removing nitrogen from a source gas mainly containing methane, a pressure swing adsorption technique is disclosed in, for example, Patent Document 2. According to this pressure swing adsorption technology, the concentration of the main component is increased when the pressure is swung up and down to adsorb the impurity to the adsorbent in the tank containing the adsorbent that adsorbs the impurity more easily than the main component. Extract gas.

この圧力スイング吸着技術による方法では、一般的に、小規模設備だからといって経済的に不利になることもない。しかし、主成分としてのメタンと不純物としての窒素を効率的に分離する吸着剤の種類は少なく、一般に高価であり、吸着剤を多く使用すると圧力スイング吸着装置全体のコストも高くなる問題がある。特に、メタンより窒素が選択的に吸着されやすい吸着剤を使う場合、メタンを主成分とする製品ガスの圧力低下が少ないため
、圧力スイング吸着技術は省エネで効率的なプロセスになるという利点があるものの、その一方で、吸着しなければならない窒素の量が多いほど、あるいは原料ガス中の窒素濃度が高いほど、必要な吸着剤は多くなるため、その分だけコスト高となるという問題がある。
In general, the method based on the pressure swing adsorption technique does not cause an economical disadvantage even if it is a small-scale facility. However, there are few types of adsorbents that efficiently separate methane as the main component and nitrogen as impurities, and they are generally expensive. If a large amount of adsorbent is used, the cost of the entire pressure swing adsorption apparatus increases. In particular, when using an adsorbent that easily adsorbs nitrogen more than methane, the pressure swing adsorption technology has the advantage of becoming an energy-saving and efficient process because the pressure drop of the product gas mainly composed of methane is small. However, on the other hand, the more the amount of nitrogen that has to be adsorbed or the higher the concentration of nitrogen in the raw material gas, the more adsorbent that is required, which increases the cost.

さらには、メタンを主成分とする原料ガスから窒素を分離して取り除く他の技術として、膜分離技術が例えば特許文献3に開示されている。この膜分離技術の方法によると、メタンよりも窒素を透過しやすい分離膜の一方側から窒素を透過させて他方側に窒素の濃度が高くなったガスを得て、上記一方側では窒素が透過して分離された分だけメタン濃度が高められたガスを得る。この膜分離技術による方法では、上記圧力スイング吸着技術による場合と同様に、一般的に、小規模設備だからといって経済的に不利になることもない。しかし、メタンと窒素を効率的に分離する分離膜の種類は少なく、一般に高価であり、分離膜を多く使用すると膜分離装置全体のコストも高くなるという問題がある。特に、メタンより窒素が選択的に透過しやすい分離膜を使う場合、メタンを主成分とする製品ガスの圧力低下が少ないため、膜分離技術は省エネで効率的なプロセスになるという利点があるが、膜分離では、膜の両側にあるガスの分圧比に応じて膜透過量が決まるため、加圧された原料ガス中の窒素ガス濃度が高い場合は、分離膜を透過する窒素ガスの量は比較的多いものの、原料ガス中の窒素ガス濃度が低い場合は、分離膜を透過する窒素ガス量は比較的小さくなり、非効率になる。したがって、製品ガスの窒素ガス濃度の目標を小さくすればするほど、分離膜の必要量がいたずらに多くなり、膜分離装置全体のコストも高くなる問題がある。   Further, as another technique for separating and removing nitrogen from a source gas containing methane as a main component, a membrane separation technique is disclosed in Patent Document 3, for example. According to the method of this membrane separation technique, nitrogen is permeated from one side of the separation membrane, which is more permeable to nitrogen than methane, and a gas having a higher nitrogen concentration is obtained on the other side. As a result, a gas with an increased methane concentration is obtained. In the method using the membrane separation technique, as in the case of the pressure swing adsorption technique, there is generally no economical disadvantage even if it is a small-scale facility. However, there are few types of separation membranes for efficiently separating methane and nitrogen, which are generally expensive, and there is a problem that the cost of the entire membrane separation device increases when many separation membranes are used. In particular, when using a separation membrane that easily allows nitrogen to permeate over methane, the pressure of the product gas containing methane as the main component is low, so the membrane separation technology has the advantage of being an energy-saving and efficient process. In membrane separation, since the membrane permeation amount is determined according to the partial pressure ratio of the gas on both sides of the membrane, when the nitrogen gas concentration in the pressurized source gas is high, the amount of nitrogen gas that permeates the separation membrane is If the nitrogen gas concentration in the raw material gas is low, the amount of nitrogen gas that permeates the separation membrane becomes relatively small and inefficient. Therefore, there is a problem that the smaller the target of the nitrogen gas concentration of the product gas, the more the required amount of the separation membrane is increased, and the cost of the entire membrane separation apparatus is increased.

また、メタンの回収率(原料ガス中のメタンの量に対する最終的に得られた製品ガス中のメタンの量の割合)も重要な点である。窒素を取り除くことができたとしても、製品としてのメタンも多くロスしてしまうと、非常に不経済であることは自明である。例えば、圧力スイング吸着技術を開示している特許文献2では、メタンを主成分とするガスから窒素を取り除く実験例においてメタン回収率が60%〜65 %と説明されているが、より高いメタン回収率が求められている。また、製品ガス中の窒素残留濃度も重要な点である。 窒素残留濃度が低いほど望ましいことは述べるまでもない。   The methane recovery rate (the ratio of the amount of methane in the product gas finally obtained to the amount of methane in the raw material gas) is also an important point. It is obvious that even if nitrogen can be removed, it is very uneconomical if a lot of methane is lost as a product. For example, in Patent Document 2 that discloses a pressure swing adsorption technique, the methane recovery rate is described as 60% to 65% in an experimental example in which nitrogen is removed from a gas containing methane as a main component. The rate is sought. The nitrogen residual concentration in the product gas is also an important point. Needless to say, the lower the residual nitrogen concentration, the better.

特開2013−036676JP2013-036676 特開2012−144628JP2012-144628 特表2004−509735Special table 2004-509735

しかしながら、メタンを主成分とする原料ガスから不純物としての窒素を取り除く技術として、特許文献1の方法では、設備が大がかりになって設備コストが高くなるし、特許文献2の方法では、不純物としての窒素の量が多いほど、そしてその窒素濃度が高いほど多くの吸着剤を要し、その分だけコスト高となるし、さらに、特許文献3の方法では、製品ガスの窒素ガス濃度の目標を小さくすればするほど、分離膜の必要量が多くなり、膜分離装置全体のコストも高くなるという問題がある。また、メタンの回収率が十分なものとなっていないという問題がある。   However, as a technique for removing nitrogen as an impurity from a source gas containing methane as a main component, the method of Patent Document 1 increases the equipment cost due to the large equipment, and the method of Patent Document 2 increases the cost as an impurity. The larger the amount of nitrogen and the higher the nitrogen concentration, the more adsorbents are required, and the cost increases accordingly. Further, in the method of Patent Document 3, the target of the nitrogen gas concentration of the product gas is reduced. There is a problem that the more the separation membrane is required, the higher the required amount of the separation membrane and the higher the cost of the entire membrane separation apparatus. In addition, there is a problem that the methane recovery rate is not sufficient.

かかる事情に鑑み、本発明は、メタンを主成分とする原料ガスから窒素を取り除くにあたって、製品ガス中の窒素残留濃度が低く、かつ、メタンの回収率が高く、経済的な窒素分離装置及び窒素分離方法を提供することを課題とする。   In view of such circumstances, the present invention provides an economical nitrogen separation device and nitrogen having a low residual nitrogen concentration in a product gas and a high methane recovery rate in removing nitrogen from a raw material gas mainly composed of methane. It is an object to provide a separation method.

本発明によれば、上述の課題は、窒素分離装置に関しては次の第一ないし第四発明のいずれによっても、また窒素分離方法に関しては、第五ないし第八発明のいずれによって解決される。   According to the present invention, the above-mentioned problems can be solved by any one of the following first to fourth inventions concerning the nitrogen separation apparatus and any of the fifth to eighth inventions concerning the nitrogen separation method.

≪窒素分離装置≫
<第一発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により第一室と第二室に区分形成されていて、第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた膜分離排ガスが第二室に収容され、原料ガスよりもメタン濃度が高められた残留窒素を含む膜分離処理ガスが第一室に収容される膜分離装置と、
メタンより窒素が選択的に吸着される吸着剤を吸着槽内に備えていて、上記膜分離装置の第一室から膜分離処理ガスを受けて、吸着槽内での圧力スイングのもとで吸着剤が膜分離処理ガス中の残留窒素を吸着することで、膜分離処理ガスよりメタン濃度が高められた製品ガスと、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスとを生ずる圧力スイング吸着装置と、
を有することを特徴とする窒素分離装置。
≪Nitrogen separator≫
<First invention>
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A separation membrane through which nitrogen is selectively permeated from methane is provided in the separation tank, and the inside of the separation tank is divided into a first chamber and a second chamber by the separation membrane, and is fed to the first chamber Membrane separation exhaust gas in which the nitrogen concentration is increased by the nitrogen in the gas permeating the separation membrane is stored in the second chamber, and the membrane separation treatment gas containing residual nitrogen in which the methane concentration is higher than the raw material gas is the first. A membrane separation device housed in the chamber;
The adsorption tank is equipped with an adsorbent that selectively adsorbs nitrogen from methane, receives the membrane separation treatment gas from the first chamber of the membrane separation device, and adsorbs under the pressure swing in the adsorption tank. The agent adsorbs the residual nitrogen in the membrane separation treatment gas, so that the product gas with a higher methane concentration than the membrane separation treatment gas and the nitrogen desorbed after being adsorbed, the nitrogen concentration is increased and contains methane. A pressure swing adsorption device that produces exhaust gas;
A nitrogen separator characterized by comprising:

<第二発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により第一室と第二室に区分形成されていて、第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた膜分離排ガスが第二室に収容され、原料ガスよりもメタン濃度が高められた残留窒素を含む膜分離処理ガスが第一室に収容される膜分離装置と、
メタンより窒素が選択的に吸着される吸着剤を吸着槽内に備えていて、上記膜分離装置の第一室から膜分離処理ガスを受けて、吸着槽内での圧力スイングのもとで吸着剤が膜分離処理ガス中の残留窒素を吸着することで、膜分離処理ガスよりメタン濃度が高められた製品ガスと、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスとを生ずる圧力スイング吸着装置と、
を有し、
排ガスの一部を圧力スイング吸着装置へ帰還供給し、残部を排出することを特徴とする窒素分離装置。
<Second invention>
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A separation membrane through which nitrogen is selectively permeated from methane is provided in the separation tank, and the inside of the separation tank is divided into a first chamber and a second chamber by the separation membrane, and is fed to the first chamber Membrane separation exhaust gas in which the nitrogen concentration is increased by the nitrogen in the gas permeating the separation membrane is stored in the second chamber, and the membrane separation treatment gas containing residual nitrogen in which the methane concentration is higher than the raw material gas is the first. A membrane separation device housed in the chamber;
The adsorption tank is equipped with an adsorbent that selectively adsorbs nitrogen from methane, receives the membrane separation treatment gas from the first chamber of the membrane separation device, and adsorbs under the pressure swing in the adsorption tank. The agent adsorbs the residual nitrogen in the membrane separation treatment gas, so that the product gas with a higher methane concentration than the membrane separation treatment gas and the nitrogen desorbed after being adsorbed, the nitrogen concentration is increased and contains methane. A pressure swing adsorption device that produces exhaust gas;
Have
A nitrogen separator characterized in that a part of the exhaust gas is fed back to the pressure swing adsorption device and the remainder is discharged.

<第三発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により第一室と第二室に区分形成されていて、第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた膜分離排ガスが第二室に収容され、原料ガスよりもメタン濃度が高められた残留窒素を含む膜分離処理ガスが第一室に収容される膜分離装置と、
メタンより窒素が選択的に吸着される吸着剤を吸着槽内に備えていて、上記膜分離装置の第一室から膜分離処理ガスを受けて、吸着槽内での圧力スイングのもとで吸着剤が膜分離処理ガス中の残留窒素を吸着することで、膜分離処理ガスよりメタン濃度が高められた製品ガスと、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスとを生ずる圧力スイング吸着装置と、
を有し、
排ガスの一部を膜分離装置の第一室へ帰還供給し、残部を排出することを特徴とする窒素分離装置。
<Third invention>
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A separation membrane through which nitrogen is selectively permeated from methane is provided in the separation tank, and the inside of the separation tank is divided into a first chamber and a second chamber by the separation membrane, and is fed to the first chamber Membrane separation exhaust gas in which the nitrogen concentration is increased by the nitrogen in the gas permeating the separation membrane is stored in the second chamber, and the membrane separation treatment gas containing residual nitrogen in which the methane concentration is higher than the raw material gas is the first. A membrane separation device housed in the chamber;
The adsorption tank is equipped with an adsorbent that selectively adsorbs nitrogen from methane, receives the membrane separation treatment gas from the first chamber of the membrane separation device, and adsorbs under the pressure swing in the adsorption tank. The agent adsorbs the residual nitrogen in the membrane separation treatment gas, so that the product gas with a higher methane concentration than the membrane separation treatment gas and the nitrogen desorbed after being adsorbed, the nitrogen concentration is increased and contains methane. A pressure swing adsorption device that produces exhaust gas;
Have
A nitrogen separator characterized in that a part of the exhaust gas is fed back to the first chamber of the membrane separator and the remainder is discharged.

<第四発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により第一室と第二室に区分形成されていて、第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた膜分離排ガスが第二室に収容され、原料ガスよりもメタン濃度が高められた残留窒素を含む膜分離処理ガスが第一室に収容される膜分離装置と、
メタンより窒素が選択的に吸着される吸着剤を吸着槽内に備えていて、上記膜分離装置の第一室から膜分離処理ガスを受けて、吸着槽内での圧力スイングのもとで吸着剤が膜分離処理ガス中の残留窒素を吸着することで、膜分離処理ガスよりメタン濃度が高められた製品ガスと、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスとを生ずる圧力スイング吸着装置とを有し、
膜分離装置は第一膜分離装置と第二膜分離装置とから成り、いずれも分離膜により区分された第一室と第二室を有し、
原料ガスは第一膜分離装置の第一室に供給され、
圧力スイング吸着装置は、窒素濃度が高められメタンを含む中圧排ガスが第一膜分離装置の第一室へ帰還供給されるように該第一膜分離装置に接続されていると共に、窒素が減圧吸引され窒素濃度が高められメタンを含む低圧排ガスが第二膜分離装置の第一室へ供給されるように該第二膜分離装置に接続されており、
第一膜分離装置の第二室は第二膜分離装置の第一室に接続されていて、該第一膜分離装置の第二室からの一次膜分離排ガスを圧力スイング吸着装置からの上記低圧排ガスと合流して第二膜分離装置の第一室へ供給するように第二膜分離装置に接続されており、
第二膜分離装置の第一室からの二次膜分離処理ガスを第一膜分離装置の第一室からの一次膜分離処理ガスに合流して圧力スイング吸着装置へ供給し、
第二膜分離装置の第二室から二次膜分離排ガスを排出する、
ことを特徴とする窒素分離装置。
<Fourth Invention>
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A separation membrane through which nitrogen is selectively permeated from methane is provided in the separation tank, and the inside of the separation tank is divided into a first chamber and a second chamber by the separation membrane, and is fed to the first chamber Membrane separation exhaust gas in which the nitrogen concentration is increased by the nitrogen in the gas permeating the separation membrane is stored in the second chamber, and the membrane separation treatment gas containing residual nitrogen in which the methane concentration is higher than the raw material gas is the first. A membrane separation device housed in the chamber;
The adsorption tank is equipped with an adsorbent that selectively adsorbs nitrogen from methane, receives the membrane separation treatment gas from the first chamber of the membrane separation device, and adsorbs under the pressure swing in the adsorption tank. The agent adsorbs the residual nitrogen in the membrane separation treatment gas, so that the product gas with a higher methane concentration than the membrane separation treatment gas and the nitrogen desorbed after being adsorbed, the nitrogen concentration is increased and contains methane. A pressure swing adsorption device that produces exhaust gas,
The membrane separator comprises a first membrane separator and a second membrane separator, both having a first chamber and a second chamber separated by a separation membrane,
The source gas is supplied to the first chamber of the first membrane separator,
The pressure swing adsorption device is connected to the first membrane separation device so that the medium pressure exhaust gas containing methane and containing methane is fed back to the first chamber of the first membrane separation device. Connected to the second membrane separator so that the low-pressure exhaust gas that is sucked in and the nitrogen concentration is increased and that contains methane is supplied to the first chamber of the second membrane separator,
The second chamber of the first membrane separation device is connected to the first chamber of the second membrane separation device, and the primary membrane separation exhaust gas from the second chamber of the first membrane separation device is subjected to the low pressure from the pressure swing adsorption device. It is connected to the second membrane separator so as to join the exhaust gas and supply it to the first chamber of the second membrane separator,
The secondary membrane separation processing gas from the first chamber of the second membrane separation device is joined to the primary membrane separation processing gas from the first chamber of the first membrane separation device and supplied to the pressure swing adsorption device,
Discharging the secondary membrane separation exhaust gas from the second chamber of the second membrane separation device,
A nitrogen separator.

≪窒素分離方法≫
<第五発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を有する膜分離装置に原料ガスを供給して該分離膜を透過させることで窒素濃度が高められた膜分離排ガスと、該原料ガスよりメタン濃度が高められた残留窒素を含む膜分離処理ガスとを上記膜分離装置で生じさせ、
メタンより窒素が選択的に吸着される吸着剤を有する圧力スイング吸着装置に上記膜分離処理ガスを供給して圧力スイングのもとで吸着剤に膜分離処理ガス中の残留窒素を吸着させることで、上記膜分離処理ガスよりメタン濃度が高められた製品ガスを上記圧力スイング吸着装置に生じさせ、
圧力スイング吸着装置から上記製品ガスを取り出すと共に、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスを排出することを特徴とする窒素分離方法。
≪Nitrogen separation method≫
<Fifth invention>
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
Membrane separation exhaust gas having a nitrogen concentration increased by supplying a raw material gas to a membrane separation apparatus having a separation membrane through which nitrogen is selectively permeated from methane and passing through the separation membrane, and a methane concentration from the raw material gas A membrane separation treatment gas containing increased residual nitrogen is generated in the membrane separation device,
By supplying the membrane separation process gas to a pressure swing adsorption device having an adsorbent that selectively adsorbs nitrogen from methane, and adsorbing the residual nitrogen in the membrane separation process gas to the adsorbent under the pressure swing , A product gas having a higher methane concentration than the membrane separation treatment gas is generated in the pressure swing adsorption device,
A method for separating nitrogen, wherein the product gas is taken out from a pressure swing adsorption device, and exhaust gas containing methane containing nitrogen with increased nitrogen concentration including nitrogen adsorbed after adsorption is discharged.

<第六発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を有する膜分離装置に原料ガスを供給して該分離膜を透過させることで窒素濃度が高められた膜分離排ガスと、該原料ガスよりメタン濃度が高められた残留窒素を含む膜分離処理ガスとを上記膜分離装置で生じさせ、
メタンより窒素が選択的に吸着される吸着剤を有する圧力スイング吸着装置に上記膜分離処理ガスを供給して圧力スイングのもとで吸着剤に膜分離処理ガス中の残留窒素を吸着させることで、上記膜分離処理ガスよりメタン濃度が高められた製品ガスを上記圧力スイング吸着装置に生じさせ、
圧力スイング吸着装置から上記製品ガスを取り出すと共に、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスの一部を圧力スイング吸着装置へ帰還供給し、残部を排出することを特徴とする窒素分離方法。
<Sixth Invention>
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
Membrane separation exhaust gas having a nitrogen concentration increased by supplying a raw material gas to a membrane separation apparatus having a separation membrane through which nitrogen is selectively permeated from methane and passing through the separation membrane, and a methane concentration from the raw material gas A membrane separation treatment gas containing increased residual nitrogen is generated in the membrane separation device,
By supplying the membrane separation process gas to a pressure swing adsorption device having an adsorbent that selectively adsorbs nitrogen from methane, and adsorbing the residual nitrogen in the membrane separation process gas to the adsorbent under the pressure swing , A product gas having a higher methane concentration than the membrane separation treatment gas is generated in the pressure swing adsorption device,
Taking out the product gas from the pressure swing adsorption device, feeding back a part of the exhaust gas containing methane containing nitrogen that has been desorbed after being adsorbed to the pressure swing adsorption device, and discharging the remainder A method for separating nitrogen.

<第七発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を有する膜分離装置に原料ガスを供給して該分離膜を透過させることで窒素濃度が高められた膜分離排ガスと、該原料ガスよりメタン濃度が高められた残留窒素を含む膜分離処理ガスとを上記膜分離装置で生じさせ、
メタンより窒素が選択的に吸着される吸着剤を有する圧力スイング吸着装置に上記膜分離処理ガスを供給して圧力スイングのもとで吸着剤に膜分離処理ガス中の残留窒素を吸着させることで、上記膜分離処理ガスよりメタン濃度が高められた製品ガスを上記圧力スイング吸着装置に生じさせ、
圧力スイング吸着装置から上記製品ガスを取り出すと共に、吸着された後に脱着された窒素を含んで窒素濃度が高められメタンを含む排ガスの一部を膜分離装置へ帰還供給し、残部を排出することを特徴とする窒素分離方法。
<Seventh invention>
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
Membrane separation exhaust gas having a nitrogen concentration increased by supplying a raw material gas to a membrane separation apparatus having a separation membrane through which nitrogen is selectively permeated from methane and passing through the separation membrane, and a methane concentration from the raw material gas A membrane separation treatment gas containing increased residual nitrogen is generated in the membrane separation device,
By supplying the membrane separation process gas to a pressure swing adsorption device having an adsorbent that selectively adsorbs nitrogen from methane, and adsorbing the residual nitrogen in the membrane separation process gas to the adsorbent under the pressure swing , A product gas having a higher methane concentration than the membrane separation treatment gas is generated in the pressure swing adsorption device,
The product gas is taken out from the pressure swing adsorption device, and a part of the exhaust gas containing nitrogen that has been desorbed after being adsorbed and whose nitrogen concentration is increased and containing methane is fed back to the membrane separation device, and the remainder is discharged. Nitrogen separation method characterized.

<第八発明>
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を有する第一膜分離装置に原料ガスを供給して該分離膜を透過させることで窒素濃度が高められた一次膜分離排ガスと、該原料ガスよりメタン濃度が高められた残留窒素を含む一次膜分離処理ガスとを上記第一膜分離装置で生じさせ、
メタンより窒素が選択的に吸着される吸着剤を有する圧力スイング吸着装置に上記一次膜分離処理ガスを供給して圧力スイングのもとで吸着剤に膜分離処理ガス中の残留窒素を吸着させることで、上記一次膜分離処理ガスよりメタン濃度が高められた製品ガスそして窒素濃度が高められメタンを含む中圧排ガス及び低圧排ガスを生じさせ、
圧力スイング吸着装置から上記製品ガスを取り出すと共に、上記中圧排ガスを第一膜分離装置へ原料ガスに合流させ帰還供給し、上記低圧排ガスを第一膜分離装置からの一次膜分離排ガスと合流させて第二膜分離装置へ供給し処理して二次膜分離処理ガスと二次膜分離排ガスとを生じさせ、二次膜分離処理ガスを一次膜分離処理ガスに合流させて圧力スイング吸着装置へ供給し、二次膜分離排ガスを排出することを特徴とする窒素分離方法。
<Eighth invention>
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A primary membrane separation exhaust gas having a nitrogen concentration increased by supplying a raw material gas to a first membrane separation device having a separation membrane through which nitrogen is selectively permeated from methane and allowing the separation membrane to pass through, and from the raw material gas A primary membrane separation treatment gas containing residual nitrogen with increased methane concentration is generated in the first membrane separation device,
The primary membrane separation treatment gas is supplied to a pressure swing adsorption device having an adsorbent that selectively adsorbs nitrogen from methane, and the adsorbent adsorbs residual nitrogen in the membrane separation treatment gas under the pressure swing. The product gas having a higher methane concentration than the primary membrane separation treatment gas, and the nitrogen concentration is increased to produce medium-pressure exhaust gas and low-pressure exhaust gas containing methane,
The product gas is taken out from the pressure swing adsorption device, the medium pressure exhaust gas is combined with the raw material gas to the first membrane separation device and fed back, and the low pressure exhaust gas is combined with the primary membrane separation exhaust gas from the first membrane separation device. And supply to the second membrane separation device to produce a secondary membrane separation processing gas and a secondary membrane separation exhaust gas, and join the secondary membrane separation processing gas to the primary membrane separation processing gas to the pressure swing adsorption device A nitrogen separation method comprising supplying and discharging secondary membrane separation exhaust gas.

上述のような本発明の第一ないし第八発明では、膜分離装置での窒素分離後に残留する窒素を圧力スイング吸着装置で吸着して両装置により二段階にわたって除去するので、両装置とも窒素除去量がさほど高くなくてすむようになり、膜分離装置では圧力低下が小さい上に、膜の使用量を抑制でき、圧力スイング吸着装置では吸着剤の使用量を抑制でき、その分のコストが低減される。   In the first to eighth inventions of the present invention as described above, the nitrogen remaining after the nitrogen separation in the membrane separator is adsorbed by the pressure swing adsorption device and removed in two stages by both devices. The amount does not need to be very high, the pressure drop is small in the membrane separation device and the amount of membrane used can be suppressed, and the amount of adsorbent used can be suppressed in the pressure swing adsorption device, thereby reducing the cost. The

第二そして第六発明では窒素濃度が高められメタンを含む排ガスの一部が圧力スイング吸着装置へ帰還供給されて排ガス中のメタンが製品ガスに移行し製品ガスに含まれるメタン量が増加するためメタンの回収率が向上するし、第三及び第四そして第七及び第八発明では、上記排ガスの一部が膜分離装置へ帰還供給されて同様にメタンの回収率が向上する。   In the second and sixth inventions, since the nitrogen concentration is increased and a part of the exhaust gas containing methane is fed back to the pressure swing adsorption device, the methane in the exhaust gas shifts to the product gas and the amount of methane contained in the product gas increases. The methane recovery rate is improved, and in the third, fourth, seventh and eighth inventions, a part of the exhaust gas is fed back to the membrane separation device, and the methane recovery rate is also improved.

このように、本発明では、膜分離装置に後続して圧力スイング吸着装置を接続することとしたので、両装置の利点を相乗作用のもとで得ることができる。   Thus, in the present invention, since the pressure swing adsorption device is connected subsequent to the membrane separation device, the advantages of both devices can be obtained under synergistic action.

ここで、本発明において、メタンを主成分とし窒素を含む原料ガスとは、1mol%以上
、より典型的には5mol%以上の窒素を含み、70mol%以上、より典型的には80mol%
以上のメタンを含むガスを指し、また、メタンより窒素が選択的に吸着しやすい吸着剤とは、特に限定されるものではないが、例えばチタノシリケート系モレキュラーシーブや、金属有機構造体を指し、さらには、メタンより窒素が選択的に透過しやすい分離膜とは、特に限定されるものではないが、例えば混合マトリックスナノポーラスカーボン膜、DDR型ゼオライト膜、CHA型ゼオライト膜を指す。
Here, in the present invention, the source gas containing methane as a main component and containing nitrogen contains 1 mol% or more, more typically 5 mol% or more of nitrogen, 70 mol% or more, more typically 80 mol%.
The above-mentioned gas containing methane, and the adsorbent in which nitrogen is more likely to be selectively adsorbed than methane are not particularly limited, but include, for example, titanosilicate molecular sieves and metal organic structures. Further, the separation membrane in which nitrogen is more selectively permeated than methane is not particularly limited, and examples thereof include a mixed matrix nanoporous carbon membrane, a DDR type zeolite membrane, and a CHA type zeolite membrane.

以上のように、本発明によると、膜分離装置での窒素分離後に残留する窒素を圧力スイング吸着装置で吸着して両装置により二段階にわたって除去し、原料ガスを膜分離処理装置により中程度まで窒素濃度を低下させ、さらに、圧力スイング吸着装置により極低濃度まで窒素濃度を低下させるので、窒素残留濃度が低くメタン濃度を高めた製品ガスを得ることができ、かつ、メタンの高い回収率を得ることができる。両装置では小型化のもとで窒素除去量がさほど高くなくてすむようになり、膜分離装置では圧力低下が小さい上に、膜の使用量を抑制でき、圧力スイング吸着装置では吸着剤の使用量を抑制でき、その分の膜及び吸着剤のコストが低減される、という効果を得る。   As described above, according to the present invention, nitrogen remaining after nitrogen separation in the membrane separation device is adsorbed by the pressure swing adsorption device and removed in two stages by both devices, and the raw material gas is moderately obtained by the membrane separation processing device. Nitrogen concentration is reduced, and further, the pressure concentration is reduced to a very low level by a pressure swing adsorption device, so that a product gas having a low residual nitrogen concentration and an increased methane concentration can be obtained, and a high methane recovery rate can be obtained. Can be obtained. In both devices, the amount of nitrogen removal does not need to be very high due to miniaturization, the pressure drop is small in the membrane separation device, and the amount of membrane used can be suppressed, and the amount of adsorbent used in the pressure swing adsorption device And the cost of the membrane and the adsorbent can be reduced.

本発明の第一実施形態装置の概要構成図である。It is a schematic block diagram of the apparatus of 1st embodiment of this invention. 第二実施形態装置の概要構成図である。It is a schematic block diagram of 2nd embodiment apparatus. 第三実施形態装置の概要構成図である。It is a schematic block diagram of 3rd embodiment apparatus. 第四実施形態装置の概要構成図である。It is a schematic block diagram of 4th embodiment apparatus.

以下、添付図面にもとづき、本発明の実施の形態について説明する。   Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

<第一実施形態>
図1は第一実施形態装置の概要構成図であり、本実施形態装置は、膜分離装置1とこれに接続された圧力スイング吸着装置2とを有している。
<First embodiment>
FIG. 1 is a schematic configuration diagram of a first embodiment apparatus, which includes a membrane separation apparatus 1 and a pressure swing adsorption apparatus 2 connected thereto.

上記膜分離装置1は、槽内に分離膜1Cを設けることで、該分離膜1Cの上流側の第一室1Aと該分離膜1Cの下流側の第二室1Bとに区分されている。上記分離膜1Cは、メタンより窒素を選択的に透過する膜であり、上記第一室1Aは、圧縮機3で原料ガス11を圧縮して得られる加圧原料ガス12を受けるようになっている。上記第二室1Bには、排ガス排出口が形成されていて、第一室1A内の加圧原料ガス12中の窒素が分離膜1Cを透過して第二室1Bに流入した後、窒素濃度が高められたガスが膜分離排ガス14として第二室1Bに設けられた排ガス排出口から排出されるようになっている。窒素が分離膜1Cを透過し分離された後に第一室1Aに残留するガスはメタン濃度が高められ残留窒素を含み膜分離処理ガス13として圧力スイング吸着装置2へ送られる。   The membrane separation apparatus 1 is divided into a first chamber 1A on the upstream side of the separation membrane 1C and a second chamber 1B on the downstream side of the separation membrane 1C by providing a separation membrane 1C in the tank. The separation membrane 1C is a membrane that selectively permeates nitrogen over methane, and the first chamber 1A receives a pressurized source gas 12 obtained by compressing the source gas 11 with the compressor 3. Yes. An exhaust gas discharge port is formed in the second chamber 1B, and nitrogen in the pressurized raw material gas 12 in the first chamber 1A passes through the separation membrane 1C and flows into the second chamber 1B, and then the nitrogen concentration The gas with the increased is discharged as a membrane separation exhaust gas 14 from an exhaust gas exhaust port provided in the second chamber 1B. The gas remaining in the first chamber 1A after nitrogen is separated by passing through the separation membrane 1C is increased in methane concentration and sent to the pressure swing adsorption device 2 as the membrane separation processing gas 13 containing residual nitrogen.

上記膜分離装置1の第一室1Aに接続された圧力スイング吸着装置2は、槽内に三本の吸着塔2A,2B,2Cを備えていて、いずれも、メタンよりも窒素を選択的に吸着しやすい吸着剤を備えている。三本の吸着塔2A,2B,2Cは、構成自体は同一であるが、吸着工程、脱着工程そして再生工程を順次行い周期的に繰り返している。   The pressure swing adsorption apparatus 2 connected to the first chamber 1A of the membrane separation apparatus 1 includes three adsorption towers 2A, 2B, and 2C in the tank, all of which selectively select nitrogen over methane. It has an adsorbent that is easy to adsorb. The three adsorption towers 2A, 2B, and 2C have the same configuration, but the adsorption process, the desorption process, and the regeneration process are sequentially performed and repeated periodically.

上記圧力スイング吸着装置2の各吸着塔2A,2B,2Cでは、吸着工程において、上記膜分離装置1の第一室1Aから膜分離処理ガス13を受け、吸着圧力に加圧されている状態で窒素を吸着剤に吸着させ、窒素が分離されメタン濃度が高められた製品ガス15を得る。次に脱着工程において、吸着塔内圧力は吸着圧力から脱圧され、吸着剤に吸着された窒素を脱着して、窒素濃度が高められメタンを含む中圧排ガス16が排出される。さらに、再生工程において、吸着塔内圧力は真空ポンプ4により減圧され、吸着剤に残留している窒素が吸引され低圧排ガス17が排出され、吸着剤が再生される。三本の吸着塔2A,2B,2Cは、それぞれ吸着工程、脱着工程そして再生工程を順次行い周期的に繰り返し、互いに位相をずらして交替で行い、連続して圧力スイング吸着操作を行うようになっている。   In the adsorption towers 2A, 2B, 2C of the pressure swing adsorption device 2, in the adsorption process, the membrane separation processing gas 13 is received from the first chamber 1A of the membrane separation device 1 and is pressurized to the adsorption pressure. Nitrogen is adsorbed on the adsorbent to obtain a product gas 15 in which the nitrogen is separated and the methane concentration is increased. Next, in the desorption step, the pressure in the adsorption tower is depressurized from the adsorption pressure, the nitrogen adsorbed by the adsorbent is desorbed, the nitrogen concentration is increased, and the medium-pressure exhaust gas 16 containing methane is discharged. Further, in the regeneration step, the pressure in the adsorption tower is reduced by the vacuum pump 4, nitrogen remaining in the adsorbent is sucked, the low-pressure exhaust gas 17 is discharged, and the adsorbent is regenerated. Each of the three adsorption towers 2A, 2B, and 2C sequentially performs an adsorption process, a desorption process, and a regeneration process, and periodically repeats them, alternately performing a phase swing adsorption operation. ing.

このような図1の第一実施形態装置のもとでは、メタンを主成分とする原料ガス中の窒素は次の要領で除去される。   Under the apparatus of the first embodiment shown in FIG. 1, nitrogen in the raw material gas containing methane as a main component is removed in the following manner.

先ず、メタンを主成分とし窒素を含む原料ガス11は、圧縮機3で加圧されて加圧原料ガス12となり、該加圧原料ガス12が膜分離装置1の第一室1Aに供給される。膜分離装置1では、窒素が分離膜1Cを透過し分離されることで、第一室1A内にメタン濃度が高められた残留窒素を含む膜分離処理ガス13が生じ、第二室1B内に窒素濃度が高められた膜分離排ガス14が生じる。   First, a raw material gas 11 containing methane as a main component and containing nitrogen is pressurized by a compressor 3 to become a pressurized raw material gas 12, and the pressurized raw material gas 12 is supplied to the first chamber 1 </ b> A of the membrane separation apparatus 1. . In the membrane separator 1, nitrogen permeates through the separation membrane 1 </ b> C, thereby generating a membrane separation processing gas 13 containing residual nitrogen with increased methane concentration in the first chamber 1 </ b> A, and in the second chamber 1 </ b> B. Membrane separation exhaust gas 14 having an increased nitrogen concentration is generated.

上記膜分離装置1の第一室1A内の膜分離処理ガス13は、圧力スイング吸着装置2に送入供給される。圧力スイング吸着装置2では、圧力スイングのもとで、吸着工程にある吸着塔2Aで吸着剤に膜分離処理ガス中の残留窒素を吸着させることで、膜分離処理ガス13よりメタン濃度が高められた製品ガス15が生じ、脱着工程にある吸着塔2Bで吸着剤に吸着された窒素が脱着され窒素濃度が高められメタンを含む中圧排ガス16が生じ、再生工程にある吸着塔2Cで吸着剤に残留している窒素が減圧吸引され低圧排ガス17が生じる。   The membrane separation processing gas 13 in the first chamber 1 </ b> A of the membrane separation device 1 is sent and supplied to the pressure swing adsorption device 2. In the pressure swing adsorption device 2, the methane concentration is higher than that of the membrane separation processing gas 13 by adsorbing residual nitrogen in the membrane separation processing gas to the adsorbent in the adsorption tower 2 </ b> A in the adsorption step under the pressure swing. Product gas 15 is generated, the nitrogen adsorbed by the adsorbent in the adsorption tower 2B in the desorption process is desorbed, the nitrogen concentration is increased, and the intermediate pressure exhaust gas 16 containing methane is generated, and the adsorbent is adsorbed in the adsorption tower 2C in the regeneration process The remaining nitrogen is sucked under reduced pressure to generate low-pressure exhaust gas 17.

かかる本実施形態では、高い窒素濃度を有する原料ガス11を膜分離装置1で処理することにより、中程度まで窒素濃度を低下させた膜分離処理ガスを得る。高い窒素濃度を中程度まで低下させるに必要な分離膜量は、高い窒素濃度を極低濃度にまで低下させるに必要な量に比べ大幅に少なくてよく、経済的な装置となる。   In this embodiment, the membrane gas having a low nitrogen concentration is obtained by processing the raw material gas 11 having a high nitrogen concentration with the membrane separator 1. The amount of separation membrane required to reduce the high nitrogen concentration to a moderate level may be significantly smaller than the amount required to reduce the high nitrogen concentration to an extremely low concentration, which is an economical device.

また、本実施形態では、中程度の窒素濃度を有する膜分離処理ガス13を、圧力スイング吸着装置2で処理することにより、極低濃度まで窒素濃度を低下させメタン濃度を高めた製品ガスを得る。中程度の窒素濃度を極低濃度まで低下させるに必要な吸着剤量は、高い窒素濃度を極低濃度まで低下させるに必要な吸着剤量より大幅に少なくてよく、経済的な装置となる。   In the present embodiment, the membrane separation processing gas 13 having a medium nitrogen concentration is processed by the pressure swing adsorption device 2 to obtain a product gas having a reduced methane concentration and an increased methane concentration. . The amount of adsorbent required to reduce the medium nitrogen concentration to a very low concentration may be significantly less than the amount of adsorbent required to reduce the high nitrogen concentration to a very low concentration, which is an economical device.

本実施形態では、加圧原料ガス12は、膜分離装置1を通過して膜分離処理ガス13となっても、圧力低下がほとんど無いため、吸着工程での圧力スイング吸着装置2への供給にあたって再圧縮の必要が無く、省エネルギーで効率的なプロセスとなる。   In this embodiment, even if the pressurized raw material gas 12 passes through the membrane separation device 1 and becomes the membrane separation processing gas 13, there is almost no pressure drop, and therefore, in the supply to the pressure swing adsorption device 2 in the adsorption process. There is no need for recompression, resulting in an energy-saving and efficient process.

このように、本実施形態は、効率的なプロセスを実現しており、次に、本実施形態装置で行われた実験の結果を示す。   As described above, the present embodiment realizes an efficient process, and next, the result of an experiment performed by the apparatus of the present embodiment is shown.

本実施形態装置による実験の結果は表1に示されているごとくであり、表1には、図1の各部におけるガスの流量、圧力及び組成が示されている。この実験では、原料ガス11の組成がメタン85mol%、窒素15mol%であり、膜分離装置1はメタンより窒素が28倍透過しやすい分離膜1Cを備え、圧力スイング吸着装置2はメタンより窒素が5倍選択的に吸着しやすい吸着剤を備えた場合の例である。   The result of the experiment by the apparatus of the present embodiment is as shown in Table 1. Table 1 shows the gas flow rate, pressure, and composition in each part of FIG. In this experiment, the composition of the raw material gas 11 is 85 mol% methane and 15 mol% nitrogen, the membrane separation apparatus 1 is equipped with a separation membrane 1C that allows nitrogen to permeate 28 times more easily than methane, and the pressure swing adsorption apparatus 2 contains nitrogen more than methane. This is an example in the case of having an adsorbent that is easily adsorbed five times selectively.

本実施形態装置による実験に用いられた圧力スイング吸着装置2の三本の吸着塔2A,2B,2Cでは、吸着工程、脱着工程、再生工程を互いに位相をずらして順次担っており、それぞれの吸着塔から抜き出される製品ガス15、中圧排ガス16、低圧排ガス17の組成や流量は瞬間的にはまちまちであるが、表1では平均化された組成や流量が示されている。   In the three adsorption towers 2A, 2B, and 2C of the pressure swing adsorption device 2 used in the experiment by the apparatus of the present embodiment, the adsorption process, the desorption process, and the regeneration process are sequentially performed with the phases shifted from each other. Although the composition and flow rate of the product gas 15, medium pressure exhaust gas 16 and low pressure exhaust gas 17 extracted from the tower vary instantaneously, Table 1 shows the averaged composition and flow rate.

表1に示されているように、原料ガス11の窒素濃度は15mol%であるが、製品ガス
15の窒素濃度は1mol%にまで低減した。また、原料ガス11に含まれるメタンの量に
対する製品ガス15に含まれるメタンの量の割合、すなわちメタン回収率は82%であった。このように、本実施形態は、高いメタン回収率と、製品ガスの低い残留窒素濃度を実現していることを確認できる。
As shown in Table 1, the nitrogen concentration of the raw material gas 11 was 15 mol%, but the nitrogen concentration of the product gas 15 was reduced to 1 mol%. The ratio of the amount of methane contained in the product gas 15 to the amount of methane contained in the raw material gas 11, that is, the methane recovery rate was 82%. Thus, this embodiment can confirm that the high methane recovery rate and the low residual nitrogen concentration of product gas are realized.

Figure 0006136074
Figure 0006136074

<第二実施形態>
次に、図2にもとづき、本発明の第二実施形態について説明する。
<Second embodiment>
Next, based on FIG. 2, a second embodiment of the present invention will be described.

図2に示される本実施形態は、図1に示された前実施形態装置に比し、圧力スイング吸着装置2からの中圧排ガス16Aが排出されず圧縮機5により圧縮されて加圧され圧力スイング吸着装置2の入口側へ帰還供給されている点に特徴がある。その他は、図1装置と同じであるので、図1と共通部位に同一符号を付すことで、その説明を省略する。   In the present embodiment shown in FIG. 2, the medium pressure exhaust gas 16A from the pressure swing adsorption device 2 is not discharged but compressed and pressurized by the compressor 5 as compared with the previous embodiment device shown in FIG. It is characterized in that it is fed back to the inlet side of the swing adsorption device 2. The rest of the configuration is the same as that of the apparatus shown in FIG.

かかる本実施形態では、膜分離装置1の第一室1Aから圧力スイング吸着装置2へ送入される膜分離処理ガス13は、該圧力スイング吸着装置2からの中圧排ガス16Aと合流して、合流ガス18として圧力スイング吸着装置2に供給される。こうすることで、圧力スイング吸着装置2では、膜分離処理ガス13よりメタン濃度が高められた製品ガス15、窒素濃度が高められメタンを含む中圧排ガス16A、吸着剤に残留している窒素が減圧吸引された低圧排ガス17が生じる。製品ガス15は、そのまま製品として取り出されるが、第一実施形態におけるごとく排出されることなく、中圧排ガス16Aは、圧縮機5で加圧されて膜分離処理ガス13に見合った圧力のもとで膜分離処理ガス13と合流し合流ガス18を形成し圧力スイング吸着装置2へ供給される。したがって、中圧排ガス16Aが再び圧力スイング吸着装置2で圧力スイング吸着されることで該中圧排ガス16Aの一部が製品ガス15となり、その分製品ガスの量を高める。   In this embodiment, the membrane separation processing gas 13 fed from the first chamber 1A of the membrane separation device 1 to the pressure swing adsorption device 2 merges with the medium pressure exhaust gas 16A from the pressure swing adsorption device 2, The combined gas 18 is supplied to the pressure swing adsorption device 2. By doing so, in the pressure swing adsorption device 2, the product gas 15 having a higher methane concentration than the membrane separation treatment gas 13, the medium pressure exhaust gas 16 </ b> A containing methane with a higher nitrogen concentration, and the nitrogen remaining in the adsorbent are contained. Low-pressure exhaust gas 17 sucked under reduced pressure is generated. The product gas 15 is taken out as a product as it is, but without being discharged as in the first embodiment, the medium-pressure exhaust gas 16A is pressurized by the compressor 5 and under a pressure corresponding to the membrane separation processing gas 13. Then, it merges with the membrane separation processing gas 13 to form a merged gas 18, which is supplied to the pressure swing adsorption device 2. Accordingly, when the intermediate pressure exhaust gas 16A is again pressure swing adsorbed by the pressure swing adsorption device 2, a part of the intermediate pressure exhaust gas 16A becomes the product gas 15, and the amount of the product gas is increased accordingly.

本実施形態による実験の結果は、表2に示されているごとくである。   The results of the experiment according to the present embodiment are as shown in Table 2.

表2には、図2の各ガスの流量、圧力及び組成が示されている。この実験では、第一実施形態装置における実験の場合と同様に、原料ガス11の組成がメタン85mol%、窒素
15mol%であり、膜分離装置1はメタンより窒素が28倍透過しやすい分離膜1Cを備
え、圧力スイング吸着装置2はメタンより窒素が5倍選択的に吸着しやすい吸着剤を備えた場合の例である。
Table 2 shows the flow rate, pressure, and composition of each gas in FIG. In this experiment, as in the case of the experiment in the first embodiment, the composition of the raw material gas 11 is 85 mol% of methane and 15 mol% of nitrogen, and the membrane separation apparatus 1 is a separation membrane 1C in which nitrogen permeates 28 times more easily than methane. The pressure swing adsorption device 2 is an example in which an adsorbent that easily adsorbs nitrogen five times more selectively than methane is provided.

表2に示されているように、原料ガス11の窒素濃度は15mol%であるが、製品ガス
15の窒素濃度は3mol%にまで低減した。また、原料ガス11に含まれるメタンの量に
対する製品ガス15に含まれるメタンの量の割合、すなわちメタン回収率は90%であり、第一実施形態装置における実験の場合よりメタン回収率が高い値となった。
As shown in Table 2, the nitrogen concentration of the raw material gas 11 was 15 mol%, but the nitrogen concentration of the product gas 15 was reduced to 3 mol%. Further, the ratio of the amount of methane contained in the product gas 15 to the amount of methane contained in the raw material gas 11, that is, the methane recovery rate is 90%, and the methane recovery rate is higher than in the case of the experiment in the first embodiment apparatus. It became.

本実施形態における実験では、メタン濃度が64mol%とメタンを多く含む中圧排ガス
を排出せずに圧力スイング吸着装置に帰還供給して再度窒素を分離することによって、メタン回収率が向上した。このように、本実施形態は、製品ガスの低い残留窒素濃度を実現し、第一実施形態よりさらに高いメタン回収率を実現していることを確認できる。
In the experiment in this embodiment, the methane recovery rate was improved by feeding back to the pressure swing adsorption device and separating nitrogen again without discharging the medium pressure exhaust gas containing methane concentration of 64 mol% and a large amount of methane. Thus, this embodiment can confirm that the low residual nitrogen density | concentration of product gas is implement | achieved and the methane recovery rate higher than 1st embodiment is implement | achieved.

Figure 0006136074
Figure 0006136074

<第三実施形態>
次に、図3にもとづき、本発明の第三実施形態について説明する。
<Third embodiment>
Next, a third embodiment of the present invention will be described with reference to FIG.

図3に示される本実施形態は、図1に示された前実施形態装置に比し、圧力スイング吸着装置2からの中圧排ガス16Bが排出されず圧縮機5により圧縮され加圧されて膜分離装置1の第一室1Aの入口側へ帰還供給されている点に特徴がある。その他は、図1装置と同じであるので、図1と共通部位に同一符号を付すことで、その説明を省略する。   Compared with the apparatus of the previous embodiment shown in FIG. 1, the present embodiment shown in FIG. 3 does not discharge the medium-pressure exhaust gas 16B from the pressure swing adsorption device 2 but is compressed and pressurized by the compressor 5 to form a membrane. It is characterized in that it is fed back to the inlet side of the first chamber 1A of the separation device 1. The rest of the configuration is the same as that of the apparatus shown in FIG.

かかる本実施形態では、メタンを主成分とし窒素を含む原料ガス11は、圧縮機5で加圧され加圧原料ガス12となり、中圧排ガス16Bと合流して合流ガス19として、膜分離装置1の第一室1Aへ供給される。圧力スイング吸着装置2では、膜分離処理ガス13よりメタン濃度が高められた製品ガス15、窒素濃度が高められメタンを含む中圧排ガス16B、吸着剤に残留している窒素が減圧吸引された低圧排ガス17が生じる。中圧排ガス16Bは、第一実施形態におけるようには排出されずに、圧縮機5で加圧され加圧原料ガス12に見合った圧力のもとで加圧原料ガス12と合流し、合流ガス19が上記膜分離装置1の第一室1Aへ供給される。   In this embodiment, the raw material gas 11 containing methane as a main component and containing nitrogen is pressurized by the compressor 5 to become the pressurized raw material gas 12, and merges with the intermediate pressure exhaust gas 16 </ b> B as the combined gas 19 to form the membrane separation device 1. To the first chamber 1A. In the pressure swing adsorption device 2, the product gas 15 having a higher methane concentration than the membrane separation treatment gas 13, the medium pressure exhaust gas 16 </ b> B containing methane with a higher nitrogen concentration, and the low pressure at which nitrogen remaining in the adsorbent is sucked under reduced pressure. Exhaust gas 17 is generated. The medium-pressure exhaust gas 16B is not discharged as in the first embodiment, but is compressed by the compressor 5 and merged with the pressurized raw material gas 12 under a pressure commensurate with the pressurized raw material gas 12. 19 is supplied to the first chamber 1A of the membrane separation apparatus 1.

本実施形態装置による実験の結果は、表3に示されているごとくである。   The results of the experiment using the apparatus of this embodiment are as shown in Table 3.

表3には、図3の各ガスの流量、圧力及び組成が示されている。この実験では、第一実施形態装置における実験の場合と同様に、原料ガス11の組成がメタン85mol%、窒素
15mol%であり、膜分離装置1はメタンより窒素が28倍透過しやすい分離膜1Cを備
え、圧力スイング吸着装置2はメタンより窒素が5倍選択的に吸着しやすい吸着剤を備えた場合の例である。
Table 3 shows the flow rate, pressure, and composition of each gas in FIG. In this experiment, as in the case of the experiment in the first embodiment, the composition of the raw material gas 11 is 85 mol% of methane and 15 mol% of nitrogen, and the membrane separation apparatus 1 is a separation membrane 1C in which nitrogen permeates 28 times more easily than methane. The pressure swing adsorption device 2 is an example in which an adsorbent that easily adsorbs nitrogen five times more selectively than methane is provided.

表3に示されているように、原料ガス11の窒素濃度は15mol%であるが、製品ガス
15の窒素濃度は1mol%にまで低減した。また、原料ガス11に含まれるメタンの量に
対する製品ガス15に含まれるメタンの量の割合、すなわちメタン回収率は90%であり、第一実施形態装置における実験の場合よりメタン回収率が高い値となった。
As shown in Table 3, the nitrogen concentration of the raw material gas 11 was 15 mol%, but the nitrogen concentration of the product gas 15 was reduced to 1 mol%. Further, the ratio of the amount of methane contained in the product gas 15 to the amount of methane contained in the raw material gas 11, that is, the methane recovery rate is 90%, and the methane recovery rate is higher than in the case of the experiment in the first embodiment apparatus. It became.

本実施形態における実験では、メタン濃度が65mol%とメタンを多く含む中圧排ガス
を排出せずに膜分離装置に帰還供給して再度窒素を分離することによって、メタン回収率が向上した。このように、本実施形態は、製品ガスの低い残留窒素濃度を実現し、第一実施形態よりさらに高いメタン回収率を実現していることを確認できる。
In the experiment in the present embodiment, the methane recovery rate was improved by feeding back to the membrane separation apparatus and separating nitrogen again without discharging medium pressure exhaust gas containing methane concentration of 65 mol% and a large amount of methane. Thus, this embodiment can confirm that the low residual nitrogen density | concentration of product gas is implement | achieved and the methane recovery rate higher than 1st embodiment is implement | achieved.

Figure 0006136074
Figure 0006136074

<第四実施形態>
次に、図4にもとづき、本発明の第四実施形態について説明する。
<Fourth embodiment>
Next, a fourth embodiment of the present invention will be described with reference to FIG.

図4に示される本実施形態は、図3に示された前実施形態装置に比し、膜分離装置が第一膜分離装置1と第二膜分離装置51の二つの膜分離装置から成っていて、加圧原料ガス12を受ける第一膜分離装置1からの第一膜分離排ガス14と、該第一膜分離装置1からの第一膜分離処理ガスを受けて圧力スイング吸着を行う圧力スイング吸着装置2で発生する低圧排ガス17を第二膜分離装置51へ供給すると共に、該第二膜分離装置51からの第二膜分離処理ガス55を上記圧力スイング吸着装置2へ帰還供給することで再利用して、メタン回収率を高めることに特徴がある。本実施形態装置において、第一膜分離装置1が前実施形態装置における膜分離装置1に対応し、これに追加されたのが第二膜分離装置51である。   Compared with the apparatus of the previous embodiment shown in FIG. 3, the present embodiment shown in FIG. 4 includes two membrane separation devices, a first membrane separation device 1 and a second membrane separation device 51. The first membrane separation exhaust gas 14 from the first membrane separation device 1 that receives the pressurized raw material gas 12 and the pressure swing that receives the first membrane separation processing gas from the first membrane separation device 1 and performs pressure swing adsorption By supplying the low-pressure exhaust gas 17 generated in the adsorption device 2 to the second membrane separation device 51 and feeding back the second membrane separation processing gas 55 from the second membrane separation device 51 to the pressure swing adsorption device 2. It is characterized by increasing the methane recovery rate through reuse. In the present embodiment apparatus, the first membrane separation apparatus 1 corresponds to the membrane separation apparatus 1 in the previous embodiment apparatus, and a second membrane separation apparatus 51 is added thereto.

図4装置にて、図3装置と共通部位に同一符号を付すことで、その説明を省略する。   In FIG. 4 apparatus, the same code | symbol is attached | subjected to a common part with FIG. 3, and the description is abbreviate | omitted.

第二膜分離装置51は、第一膜分離装置1と同様に、メタンよりも窒素を選択的に透過する分離膜51Cにより槽内が上流側の第一室51Aと下流側の第二室51Bとに区別されている。   Similarly to the first membrane separation device 1, the second membrane separation device 51 has an upstream first chamber 51A and a downstream second chamber 51B by a separation membrane 51C that selectively permeates nitrogen rather than methane. And are distinguished.

第一室51Aは、該第一室51Aの入口側が第一膜分離装置1の第二室1Bからの第一膜分離排ガス14を圧縮機52を経て受けると共に、圧力スイング吸着装置2からの低圧排ガス17を圧縮機58を経て受けるように、第一膜分離装置1と圧力スイング吸着装置2とそれぞれ接続されている。さらに、上記第一室51Aの出口側は、該第一室51Aからの第二膜分離処理ガス55が、第一膜分離装置1の第一室1Aからの第一膜分離処理ガス13と合流して第二合流ガス56を形成するように、上記圧力スイング吸着装置2の入口側と接続されている。   In the first chamber 51A, the inlet side of the first chamber 51A receives the first membrane separation exhaust gas 14 from the second chamber 1B of the first membrane separation device 1 through the compressor 52 and the low pressure from the pressure swing adsorption device 2. The first membrane separation device 1 and the pressure swing adsorption device 2 are connected so as to receive the exhaust gas 17 through the compressor 58. Further, at the outlet side of the first chamber 51A, the second membrane separation processing gas 55 from the first chamber 51A merges with the first membrane separation processing gas 13 from the first chamber 1A of the first membrane separation device 1. Thus, it is connected to the inlet side of the pressure swing adsorption device 2 so as to form the second combined gas 56.

かかる本実施形態では、メタンを主成分とし窒素を含む原料ガス11は、圧縮機5で加圧され加圧原料ガス12となり、圧力スイング吸着装置2からの中圧排ガス16Bと合流して第一合流ガス19として、第一膜分離装置1の第一室1Aへ供給される。圧力スイング吸着装置2では、第一膜分離処理ガス13よりメタン濃度が高められた製品ガス15、窒素濃度が高められメタンを含む中圧排ガス16B、吸着剤に残留している窒素が減圧吸引された低圧排ガス17が生じる。中圧排ガス16Bは、圧縮機5で加圧され加圧原料ガス12に見合った圧力のもとで加圧原料ガス12と合流し、第一合流ガス19が上記第一膜分離装置1の第一室1Aへ供給される。   In this embodiment, the raw material gas 11 containing methane as a main component and containing nitrogen is pressurized by the compressor 5 to become the pressurized raw material gas 12, and merges with the medium pressure exhaust gas 16 </ b> B from the pressure swing adsorption device 2. The combined gas 19 is supplied to the first chamber 1 </ b> A of the first membrane separation device 1. In the pressure swing adsorption device 2, the product gas 15 having a higher methane concentration than the first membrane separation treatment gas 13, the medium pressure exhaust gas 16 </ b> B containing methane with a higher nitrogen concentration, and the nitrogen remaining in the adsorbent are sucked under reduced pressure. A low pressure exhaust gas 17 is generated. The medium pressure exhaust gas 16B is pressurized by the compressor 5 and merges with the pressurized raw material gas 12 under a pressure commensurate with the pressurized raw material gas 12, and the first combined gas 19 is the first of the first membrane separation device 1. It is supplied to one room 1A.

第一膜分離装置1の第一室1Aからの第一膜分離排ガス14は圧縮機52にて加圧され、圧力スイング吸着装置2からの低圧排ガス17は圧縮機58にて加圧されて、両者は合流して合流排ガス53となり第二膜分離装置51の第一室51Aに供給される。   The first membrane separation exhaust gas 14 from the first chamber 1A of the first membrane separation device 1 is pressurized by the compressor 52, and the low pressure exhaust gas 17 from the pressure swing adsorption device 2 is pressurized by the compressor 58, The two merge to form a merged exhaust gas 53, which is supplied to the first chamber 51A of the second membrane separation device 51.

第二膜分離装置51では、第一室51A内へ流入した合流排ガス53中の窒素が分離膜51Cを透過して第二室51Bに流入した後、窒素濃度が高められたガスが第二膜分離排ガス54として第二室51Bに設けられた排ガス排出口から排出される。窒素が分離膜51Cを透過し分離された後に第一室51Aに残留するガスはメタン濃度が高められ残留窒素を含み第二膜分離処理ガス55として上記第一膜分離装置1からの第一膜分離処理ガス13と共に第二合流ガス56を形成して圧力スイング吸着装置2へ送られる。   In the second membrane separation device 51, after the nitrogen in the combined exhaust gas 53 that has flowed into the first chamber 51 </ b> A permeates the separation membrane 51 </ b> C and flows into the second chamber 51 </ b> B, the gas whose nitrogen concentration is increased The separated exhaust gas 54 is discharged from an exhaust gas discharge port provided in the second chamber 51B. The gas remaining in the first chamber 51A after nitrogen is separated through the separation membrane 51C is increased in methane concentration and contains residual nitrogen as the second membrane separation processing gas 55 from the first membrane from the first membrane separation device 1. A second combined gas 56 is formed together with the separation processing gas 13 and sent to the pressure swing adsorption device 2.

本実施形態装置による実験の結果は、表4に示されているごとくである。   The result of the experiment by the apparatus of this embodiment is as shown in Table 4.

表4には、図4の各ガスの流量、圧力及び組成が示されている。この実験では、第一実施形態装置における実験の場合と同様に、原料ガス11の組成がメタン85mol%、窒素15mol%であり、第一膜分離装置1および第二膜分離装置51はメタンより窒素が28倍透過しやすい分離膜1Cもしくは分離膜51Cを備え、圧力スイング吸着装置2はメタンより窒素が5倍選択的に吸着しやすい吸着剤を備えた場合の例である。   Table 4 shows the flow rate, pressure, and composition of each gas in FIG. In this experiment, as in the case of the experiment in the first embodiment, the composition of the raw material gas 11 is 85 mol% of methane and 15 mol% of nitrogen, and the first membrane separator 1 and the second membrane separator 51 are more nitrogenous than methane. Is a separation membrane 1C or separation membrane 51C that is 28 times easier to permeate, and the pressure swing adsorption device 2 is an example in which an adsorbent that easily adsorbs nitrogen five times more selectively than methane is provided.

表4に示されているように、原料ガス11の窒素濃度は15mol%であるが、製品ガス15の窒素濃度は1mol%にまで低減した。また、原料ガス11に含まれるメタンの量に対する製品ガス15に含まれるメタンの量の割合、すなわちメタン回収率は98%であり、第三実施形態装置における実験の場合よりメタン回収率が高い値となった。   As shown in Table 4, the nitrogen concentration of the raw material gas 11 was 15 mol%, but the nitrogen concentration of the product gas 15 was reduced to 1 mol%. Further, the ratio of the amount of methane contained in the product gas 15 to the amount of methane contained in the raw material gas 11, that is, the methane recovery rate is 98%, which is a value higher than the case of the experiment in the third embodiment apparatus. It became.

本実施形態における実験では、メタン濃度が65mol%とメタンを多く含む中圧排ガスを排出せずに膜分離装置に帰還供給して再度窒素を分離することと、第一膜分離装置1からの第一膜分離排ガス14と圧力スイング吸着装置2からの低圧排ガス17とを圧縮後に第二膜分離装置51で再び膜分離処理することで、メタン回収率が向上した。このように、本実施形態は、製品ガスの低い残留窒素濃度を実現し、第三実施形態よりさらに高いメタン回収率を実現していることを確認できる。   In the experiment in the present embodiment, the intermediate pressure exhaust gas containing methane concentration of 65 mol% and a large amount of methane is fed back to the membrane separation device without being discharged, and the nitrogen is separated again from the first membrane separation device 1. The methane recovery rate was improved by subjecting the single membrane separation exhaust gas 14 and the low pressure exhaust gas 17 from the pressure swing adsorption device 2 to the membrane separation treatment again by the second membrane separation device 51 after compression. Thus, this embodiment can confirm that the low residual nitrogen concentration of product gas is realized and the methane recovery rate higher than the third embodiment is realized.

Figure 0006136074
Figure 0006136074

1 (第一)膜分離装置
1A 第一室
1B 第二室
1C 分離膜
2 圧力スイング吸着装置
11 原料ガス
13 (第一)膜分離処理ガス
16 中圧排ガス
17 低圧排ガス
51 第二膜分離装置
51A 第一室
51B 第二室
51C 分離膜
55 第二膜分離処理ガス
1 (First) Membrane Separator 1A First Chamber 1B Second Chamber 1C Separation Membrane 2 Pressure Swing Adsorber 11 Source Gas 13 (First) Membrane Separation Process Gas 16 Medium Pressure Exhaust Gas 17 Low Pressure Exhaust Gas 51 Second Membrane Separator 51A First chamber 51B Second chamber 51C Separation membrane 55 Second membrane separation treatment gas

Claims (6)

メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により上流側の第一室と下流側の第二室に区分形成されていて、加圧され第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた膜分離排ガスが第二室に収容され、原料ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより原料ガスよりもメタン濃度が高められ残留窒素を含み加圧されている膜分離処理ガスが第一室に収容される膜分離装置と、
メタンより窒素が選択的に吸着される吸着剤を備えた少なくとも三本の吸着塔を備えていて、それぞれの吸着塔が吸着工程、脱着工程そして再生工程を順次互いに位相をずらして交替で行い、吸着工程にて膜分離装置の第一室から加圧されている膜分離処理ガスを受けて、吸着圧力に加圧されている状態で吸着剤が膜分離処理ガス中の残留窒素を吸着し、窒素濃度が低下することにより膜分離処理ガスよりメタン濃度が高められた製品ガスを生成し、脱着工程にて吸着圧力から脱圧された脱着圧力下で吸着剤に吸着された窒素を脱着し脱着された窒素を含んで膜分離処理ガスより窒素濃度が高められメタンを含む中圧排ガスを生成し、再生工程にて減圧下で吸着剤に残留している窒素を減圧吸引し低圧排ガスを生成する圧力スイング吸着装置と、
中圧排ガスを加圧し圧力スイング吸着装置の入口側へ帰還供給し膜分離装置の第一室からの膜分離処理ガスと合流させて圧力スイング吸着装置へ供給する中圧排ガス帰還供給ラインと、を有することを特徴とする窒素分離装置。
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A separation membrane through which nitrogen is selectively permeated from methane is provided in the separation tank, and the inside of the separation tank is divided into a first chamber on the upstream side and a second chamber on the downstream side by the separation membrane, and is pressurized. Membrane separation exhaust gas whose nitrogen concentration is increased by nitrogen in the source gas sent to the first chamber permeates through the separation membrane is stored in the second chamber, and nitrogen in the source gas permeates the separation membrane and separates it. a membrane separation apparatus membrane separation process gas residual nitrogen concentration of methane is higher than the raw material gas is pressurized unrealized pressurized is housed in the first chamber by being nitrogen concentration is reduced to,
It has at least three adsorption towers equipped with an adsorbent that selectively adsorbs nitrogen from methane, and each adsorption tower performs an adsorption process, a desorption process, and a regeneration process alternately in phase with each other, In the adsorption process, the membrane separation process gas that has been pressurized is received from the first chamber of the membrane separation apparatus, and the adsorbent adsorbs residual nitrogen in the membrane separation process gas while being pressurized to the adsorption pressure . A product gas with a higher methane concentration than the membrane separation treatment gas is generated due to a decrease in nitrogen concentration, and nitrogen adsorbed on the adsorbent is desorbed and desorbed under the desorption pressure desorbed from the adsorption pressure in the desorption process. It is to produce a pressure gas inside including the nitrogen containing methane nitrogen concentration increased from membrane separation process gas and vacuum suction nitrogen remaining in the adsorbent under reduced pressure at a regeneration step for generating a low-pressure exhaust gas Pressure swing adsorption device ,
A retraction gas recirculation supply line during feeding to the pressure swing adsorber membrane separation process is combined with the gas from the first chamber of the returned supplying medium pressure exhaust gas to the inlet side of the pressurizing pressure swing adsorption unit membrane separation device, the A nitrogen separator characterized by having.
メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により上流側の第一室と下流側の第二室に区分形成されていて、加圧され第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた膜分離排ガスが第二室に収容され、原料ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより原料ガスよりもメタン濃度が高められ残留窒素を含み加圧されている膜分離処理ガスが第一室に収容される膜分離装置と、
メタンより窒素が選択的に吸着される吸着剤を備えた少なくとも三本の吸着塔を備えていて、それぞれの吸着塔が吸着工程、脱着工程そして再生工程を順次互いに位相をずらして交替で行い、吸着工程にて膜分離装置の第一室から加圧されている膜分離処理ガスを受けて、吸着圧力に加圧されている状態で吸着剤が膜分離処理ガス中の残留窒素を吸着し、窒素濃度が低下することにより膜分離処理ガスよりメタン濃度が高められた製品ガスを生成し、脱着工程にて吸着圧力から脱圧された脱着圧力下で吸着剤に吸着された窒素を脱着し脱着された窒素を含んで膜分離処理ガスより窒素濃度が高められメタンを含む中圧排ガスを生成し、再生工程にて減圧下で吸着剤に残留している窒素を減圧吸引し低圧排ガスを生成する圧力スイング吸着装置と、
中圧排ガスを加圧し膜分離装置の入口側へ帰還供給し原料ガスと合流させて膜分離装置へ供給する中圧排ガス帰還供給ラインと、を有することを特徴とする窒素分離装置。
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
A separation membrane through which nitrogen is selectively permeated from methane is provided in the separation tank, and the inside of the separation tank is divided into a first chamber on the upstream side and a second chamber on the downstream side by the separation membrane, and is pressurized. Membrane separation exhaust gas whose nitrogen concentration is increased by nitrogen in the source gas sent to the first chamber permeates through the separation membrane is stored in the second chamber, and nitrogen in the source gas permeates the separation membrane and separates it. a membrane separation apparatus membrane separation process gas residual nitrogen concentration of methane is higher than the raw material gas is pressurized unrealized pressurized is housed in the first chamber by being nitrogen concentration is reduced to,
It has at least three adsorption towers equipped with an adsorbent that selectively adsorbs nitrogen from methane, and each adsorption tower performs an adsorption process, a desorption process, and a regeneration process alternately in phase with each other, In the adsorption process, the membrane separation process gas that has been pressurized is received from the first chamber of the membrane separation apparatus, and the adsorbent adsorbs residual nitrogen in the membrane separation process gas while being pressurized to the adsorption pressure . A product gas with a higher methane concentration than the membrane separation treatment gas is generated due to a decrease in nitrogen concentration, and nitrogen adsorbed on the adsorbent is desorbed and desorbed under the desorption pressure desorbed from the adsorption pressure in the desorption process. It is to produce a pressure gas inside including the nitrogen containing methane nitrogen concentration increased from membrane separation process gas and vacuum suction nitrogen remaining in the adsorbent under reduced pressure at a regeneration step for generating a low-pressure exhaust gas Pressure swing adsorption device ,
An intermediate pressure exhaust gas return supply line that pressurizes medium pressure exhaust gas, feeds it back to the inlet side of the membrane separation apparatus, joins it with the raw material gas, and supplies it to the membrane separation apparatus.
メタンを主成分とし窒素を含む原料ガスから窒素を分離する装置において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により上流側の第一室と下流側の第二室に区分形成されている第一膜分離装置と第二膜分離装置と、圧力スイング吸着装置とを有し、
第一膜分離装置は、加圧され第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた一次膜分離排ガス第二室に収容し、原料ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより原料ガスよりもメタン濃度が高められ残留窒素を含み加圧されている一次膜分離処理ガス第一室に収容し、
第二膜分離装置は、その第一室と第一膜分離装置の第二室とが接続され、第一膜分離装置第二室から供給され加圧された一次膜分離排ガスを第一室に受け入れ、一次膜分離排ガス中の窒素が分離膜を透過することで窒素濃度が高められた二次膜分離排ガスを第二室に収容し、一次膜分離排ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより一次膜分離排ガスよりもメタン濃度が高められ残留窒素を含み加圧されている二次膜分離処理ガスを第一室に収容し、
圧力スイング吸着装置は、メタンより窒素が選択的に吸着される吸着剤を備えた少なくとも三本の吸着塔を備えていて、それぞれの吸着塔が吸着工程、脱着工程そして再生工程を順次互いに位相をずらして交替で行い、吸着工程にて第一膜分離装置の第一室から加圧されている一次膜分離処理ガスを受けて、吸着圧力に加圧されている状態で吸着剤が一次膜分離処理ガス中の残留窒素を吸着し、窒素濃度が低下することにより一次膜分離処理ガスよりメタン濃度が高められた製品ガスを生成し、脱着工程にて吸着圧力から脱圧された脱着圧力下で吸着剤に吸着された窒素を脱着し脱着された窒素を含んで一次膜分離処理ガスより窒素濃度が高められメタンを含む中圧排ガスを生成し、再生工程にて減圧下で吸着剤に残留している窒素を減圧吸引し低圧排ガスを生成し、
さらに、圧力スイング吸着装置からの中圧排ガスを加圧し第一膜分離装置の入口側へ帰還供給し原料ガスと合流させて第一膜分離装置へ供給する中圧排ガス帰還供給ラインと、
圧力スイング吸着装置からの低圧排ガスを加圧し第二膜分離装置の入口側へ供給し第一膜分離装置第二室からの一次膜分離排ガスと合流させて第二膜分離装置へ供給する低圧排ガス供給ラインと、
第二膜分離装置の第一室からの二次膜分離処理ガスを圧力スイング吸着装置の入口側へ供給し第一膜分離装置の第一室からの一次膜分離処理ガス合流させて圧力スイング吸着装置へ供給する二次膜分離処理ガス供給ラインと、を有することを特徴とする窒素分離装置。
In an apparatus for separating nitrogen from a source gas containing methane as a main component and nitrogen,
The first membrane separation The separation tank has a separation membrane nitrogen from methane is selectively transmitted into the separation tank that is divided form to the second chamber of the first chamber of the upstream and downstream sides by separating membranes An apparatus, a second membrane separation device, and a pressure swing adsorption device,
The first membrane separation device accommodates in the second chamber the primary membrane separation exhaust gas whose nitrogen concentration has been increased by the nitrogen in the source gas pressurized and fed into the first chamber through the separation membrane. housing the primary membrane separation process gas nitrogen gas is a residual nitrogen concentration of methane is higher than the raw material gas by being transmitted to separate the separation membrane nitrogen concentration is lowered is pressurized unrealized pressurized in the first chamber And
In the second membrane separation device, the first chamber and the second chamber of the first membrane separation device are connected, and the primary membrane separation exhaust gas supplied from the second chamber of the first membrane separation device and pressurized is supplied to the first chamber. The secondary membrane separation exhaust gas whose nitrogen concentration is increased by the nitrogen in the primary membrane separation exhaust gas permeating through the separation membrane is accommodated in the second chamber, and the nitrogen in the primary membrane separation exhaust gas permeates the separation membrane and separates it. The secondary membrane separation process gas which is increased in methane concentration than the primary membrane separation exhaust gas and containing residual nitrogen by being reduced in nitrogen concentration is contained in the first chamber,
The pressure swing adsorption device has at least three adsorption towers equipped with an adsorbent that selectively adsorbs nitrogen from methane, and each adsorption tower sequentially performs an adsorption process, a desorption process, and a regeneration process in phase with each other. In the adsorption process, the primary membrane separation gas is pressurized from the first chamber of the first membrane separation device in the adsorption process, and the adsorbent is separated into the primary membrane while being pressurized to the adsorption pressure. Residual nitrogen in the process gas is adsorbed , and a product gas with a higher methane concentration than the primary membrane separation process gas is generated by reducing the nitrogen concentration, and under the desorption pressure that is depressurized from the adsorption pressure in the desorption process. the adsorbed nitrogen on the adsorbent generates pressure gas in containing desorbed desorbed nitrogen elevated nitrogen concentration than the primary membrane separation process gases include methane, it remains on the adsorbent under reduced pressure at regeneration step Vacuum suction of nitrogen And to generate a low-pressure exhaust gas,
Further, an intermediate pressure exhaust gas feedback supply line that pressurizes the medium pressure exhaust gas from the pressure swing adsorption device, feeds it back to the inlet side of the first membrane separation device, joins the raw material gas, and feeds it to the first membrane separation device;
Low-pressure exhaust gas pressurized from the pressure swing adsorption device, supplied to the inlet side of the second membrane separation device, joined with the primary membrane separation exhaust gas from the second chamber of the first membrane separation device, and supplied to the second membrane separation device A supply line;
The secondary membrane separation processing gas from the first chamber of the second membrane separation device is supplied to the inlet side of the pressure swing adsorption device and merged with the primary membrane separation processing gas from the first chamber of the first membrane separation device, and the pressure swing nitrogen separation device, characterized by chromatic secondary membrane separation process gas supply line for supplying to the adsorption device.
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を分離槽内に有し該分離槽内が分離膜により上流側の第一室と下流側の第二室に区分形成されている膜分離装置を用いて、加圧され第一室に送入された原料ガス中の窒素が分離膜を透過ることで窒素濃度が高められた膜分離排ガスを第二室に収容し、原料ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより原料ガスよりメタン濃度が高められ残留窒素を含み加圧されている膜分離処理ガスを第一室に収容し、
メタンより窒素が選択的に吸着される吸着剤を備えた少なくとも三本の吸着塔を備えている圧力スイング吸着装置を用いて、それぞれの吸着塔において吸着工程、脱着工程そして再生工程を順次互いに位相をずらして交替で行い、吸着工程にて膜分離装置の第一室から加圧されている膜分離処理ガスを受けて、吸着圧力に加圧されている状態で吸着剤が膜分離処理ガス中の残留窒素を吸着し、窒素濃度が低下することにより膜分離処理ガスよりメタン濃度が高められた製品ガスを生成し、脱着工程にて吸着圧力から脱圧された脱着圧力下で吸着剤に吸着された窒素を脱着し脱着された窒素を含んで膜分離処理ガスより窒素濃度が高められメタンを含む中圧排ガスを生成し、再生工程にて減圧下で吸着剤に残留している窒素を減圧吸引し低圧排ガスを生成し、
中圧排ガス帰還供給ラインを経て、中圧排ガスを加圧し圧力スイング吸着装置の入口側へ帰還供給し膜分離装置の第一室からの膜分離処理ガスと合流させて圧力スイング吸着装置へ供給することを特徴とする窒素分離方法。
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
The membrane separation apparatus nitrogen from methane is selectively transparent to the separation membrane has in the separation tank the separation tank is divided form to the second chamber of the first chamber of the upstream and downstream sides by separating membranes used to accommodate the membrane separation exhaust the nitrogen concentration at elevated Rukoto nitrogen in the feed gas fed into the first chamber is pressurized to transmit separation membrane to the second chamber, the nitrogen in the feed gas There accommodating the membrane separation process gas has a residual nitrogen concentration of methane is higher than the raw material gas is pressurized unrealized pressurized by being passed through the separation membrane separating the nitrogen concentration is reduced to the first chamber,
Using a pressure swing adsorption device with at least three adsorption towers equipped with an adsorbent that selectively adsorbs nitrogen from methane , the adsorption process, desorption process and regeneration process are sequentially phased in each adsorption tower. In the adsorption process, the membrane separation process gas pressurized from the first chamber of the membrane separation apparatus is received in the adsorption process, and the adsorbent is in the membrane separation process gas while being pressurized to the adsorption pressure. The residual nitrogen is adsorbed and a product gas with a higher methane concentration than the membrane separation treatment gas is produced by reducing the nitrogen concentration, and is adsorbed to the adsorbent under the desorption pressure desorbed from the adsorption pressure in the desorption process. nitrogen to the generation of pressure gas in containing desorbed desorbed nitrogen elevated nitrogen concentration than comprise membrane separation process gases methane, vacuum and nitrogen remaining in the adsorbent under reduced pressure at regeneration step Suction and low pressure exhaust To generate a scan,
Through the medium pressure exhaust gas recirculation supply line, for supplying the medium-pressure exhaust gas is combined with the membrane separation process gas from the first chamber of the pressurized pressure feedback supplied membrane separation unit to the inlet side of the swing adsorption device to the pressure swing adsorption device A method for separating nitrogen.
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を分離槽内にし該分離槽内が分離膜により上流側の第一室と下流側の第二室に区分形成されている膜分離装置を用いて、加圧され第一室に送入された原料ガス中の窒素が分離膜を透過ることで窒素濃度が高められた膜分離排ガスを第二室に収容し、原料ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより原料ガスよりメタン濃度が高められ残留窒素を含み加圧されている膜分離処理ガスを第一室に収容し、
メタンより窒素が選択的に吸着される吸着剤を備えた少なくとも三本の吸着塔を備えている圧力スイング吸着装置を用いて、それぞれの吸着塔において吸着工程、脱着工程そして再生工程を順次互いに位相をずらして交替で行い、吸着工程にて膜分離装置の第一室から加圧されている膜分離処理ガスを受けて、吸着圧力に加圧されている状態で吸着剤膜分離処理ガス中の残留窒素を吸着し、窒素濃度が低下することにより膜分離処理ガスよりメタン濃度が高められた製品ガスを生成し、脱着工程にて吸着圧力から脱圧された脱着圧力下で吸着剤に吸着された窒素を脱着し脱着された窒素を含んで膜分離処理ガスより窒素濃度が高められメタンを含む中圧排ガスを生成し、再生工程にて減圧下で吸着剤に残留している窒素を減圧吸引し低圧排ガスを生成し、
中圧排ガス帰還供給ラインを経て、中圧排ガスを加圧し膜分離装置の入口側へ帰還供給し原料ガスと合流させて膜分離装置へ供給することを特徴とする窒素分離方法。
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
The membrane separation apparatus nitrogen from methane is selectively transparent to the separation membrane possess in the separation tank the separation tank is divided form to the second chamber of the first chamber of the upstream and downstream sides by separating membranes used to accommodate the membrane separation exhaust the nitrogen concentration at elevated Rukoto nitrogen in the feed gas fed into the first chamber is pressurized to transmit separation membrane to the second chamber, the nitrogen in the feed gas There accommodating the membrane separation process gas has a residual nitrogen concentration of methane is higher than the raw material gas is pressurized unrealized pressurized by being passed through the separation membrane separating the nitrogen concentration is reduced to the first chamber,
Using a pressure swing adsorption device with at least three adsorption towers equipped with an adsorbent that selectively adsorbs nitrogen from methane , the adsorption process, desorption process and regeneration process are sequentially phased in each adsorption tower. carried out in alternation by shifting, by receiving the first chamber membrane separation process gas is pressurized from the membrane separation device in the adsorption step, the adsorbent membrane separation process gas in a state of being pressurized to the adsorption pressure The residual nitrogen is adsorbed and a product gas with a higher methane concentration than the membrane separation treatment gas is produced by reducing the nitrogen concentration, and is adsorbed to the adsorbent under the desorption pressure desorbed from the adsorption pressure in the desorption process. nitrogen to the generation of pressure gas in containing desorbed desorbed nitrogen elevated nitrogen concentration than comprise membrane separation process gases methane, vacuum and nitrogen remaining in the adsorbent under reduced pressure at regeneration step Suction and low pressure exhaust To generate a scan,
A nitrogen separation method characterized by pressurizing an intermediate pressure exhaust gas through an intermediate pressure exhaust gas return supply line, feeding it back to the inlet side of the membrane separation apparatus, merging it with a raw material gas and supplying it to the membrane separation apparatus .
メタンを主成分とし窒素を含む原料ガスから窒素を分離する方法において、
メタンより窒素が選択的に透過される分離膜を分離槽内にし該分離槽内が分離膜により上流側の第一室と下流側の第二室に区分形成されている第一膜分離装置と第二膜分離装置と、圧力スイング吸着装置とを用いて、
第一膜分離装置では、加圧され第一室に送入された原料ガス中の窒素が分離膜を透過することで窒素濃度が高められた一次膜分離排ガスを第二室に収容し、原料ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより原料ガスよりメタン濃度が高められ残留窒素を含み加圧されている一次膜分離処理ガスを第一室に収容し、
第二膜分離装置では、その第一室と第一膜分離装置の第二室とが接続されていて、第一膜分離装置第二室から供給され加圧された一次膜分離排ガスを第一室に受け入れ、一次膜分離排ガス中の窒素が分離膜を透過することで窒素濃度が高められた二次膜分離排ガスを第二室に収容し、一次膜分離排ガス中の窒素が分離膜を透過し分離されて窒素濃度が低下することにより一次膜分離排ガスよりメタン濃度が高められ残留窒素を含み加圧されている二次膜分離処理ガスを第一室に収容し、
圧力スイング吸着装置では、メタンより窒素が選択的に吸着される吸着剤を備えた少なくとも三本の吸着塔を用いて、それぞれの吸着塔が吸着工程、脱着工程そして再生工程を順次互いに位相をずらして交替で行い、吸着工程にて第一膜分離装置の第一室から加圧されている一次膜分離処理ガスを受けて、吸着圧力に加圧されている状態で吸着剤が一次膜分離処理ガス中の残留窒素を吸着し、窒素濃度が低下することにより一次膜分離処理ガスよりメタン濃度が高められた製品ガスを生成し、脱着工程にて吸着圧力から脱圧された脱着圧力下で吸着剤に吸着された窒素を脱着し脱着された窒素を含んで一次膜分離処理ガスより窒素濃度が高められメタンを含む中圧排ガスを生成し、再生工程にて減圧下で吸着剤に残留している窒素を減圧吸引し低圧排ガスを生成し、
さらに、中圧排ガス帰還供給ラインを経て、圧力スイング吸着装置から中圧排ガスを加圧し第一膜分離装置の入口側へ帰還供給し原料ガスと合流させて第一膜分離装置へ供給し、
低圧排ガス供給ラインを経て、圧力スイング吸着装置からの低圧排ガスを加圧し第二膜分離装置の入口側へ供給し第一膜分離装置第二室からの一次膜分離排ガスと合流させて第二膜分離装置へ供給し
二次膜分離処理ガス供給ラインを経て、第二膜分離装置の第一室からの二次膜分離処理ガスを圧力スイング吸着装置の入口側へ供給し第一膜分離装置の第一室からの一次膜分離処理ガス合流させて圧力スイング吸着装置へ供給することを特徴とする窒素分離方法。
In a method for separating nitrogen from a source gas containing methane as a main component and nitrogen,
The first membrane separation nitrogen from methane is selectively transparent to the separation membrane possess in the separation tank the separation tank is divided form to the second chamber of the first chamber of the upstream and downstream sides by separating membranes Using the device , the second membrane separation device, and the pressure swing adsorption device,
In the first membrane separation device, nitrogen in the source gas pressurized and fed into the first chamber passes through the separation membrane, and the primary membrane separation exhaust gas in which the nitrogen concentration is increased is accommodated in the second chamber. housing the primary membrane separation process gas nitrogen gas is a residual nitrogen concentration of methane is higher than the raw material gas by being transmitted to separate the separation membrane nitrogen concentration is lowered is pressurized unrealized pressurized in the first chamber And
In the second membrane separation device, the first chamber and the second chamber of the first membrane separation device are connected, and the primary membrane separation exhaust gas supplied from the second chamber of the first membrane separation device is pressurized. The secondary membrane separation exhaust gas, whose nitrogen concentration has been increased by the nitrogen in the primary membrane separation exhaust gas permeating through the separation membrane, is stored in the second chamber, and the nitrogen in the primary membrane separation exhaust gas permeates the separation membrane. was isolated by secondary membrane separation process gas is methane concentration than the primary membrane separation gas is pressurized contain residual nitrogen increased by the nitrogen concentration decreases accommodated in the first chamber,
The pressure swing adsorption device uses at least three adsorption towers equipped with an adsorbent that selectively adsorbs nitrogen from methane , and each adsorption tower sequentially shifts the phase of the adsorption process, desorption process and regeneration process. In the adsorption process, the primary membrane separation treatment gas that has been pressurized from the first chamber of the first membrane separation device is received in the adsorption process, and the adsorbent is subjected to the primary membrane separation treatment while being pressurized to the adsorption pressure. Residual nitrogen in the gas is adsorbed, and a product gas with a higher methane concentration than the primary membrane separation treatment gas is generated by reducing the nitrogen concentration, and adsorbed under the desorption pressure that is depressurized from the adsorption pressure in the desorption process. The nitrogen adsorbed on the adsorbent is desorbed, and the nitrogen concentration is increased from the primary membrane separation treatment gas containing the desorbed nitrogen to generate medium-pressure exhaust gas containing methane, which remains in the adsorbent under reduced pressure in the regeneration process Vacuum suction of nitrogen To generate a low-pressure exhaust gas,
Furthermore, through the intermediate pressure exhaust gas feedback supply line, the medium pressure exhaust gas from the pressure swing adsorption device is pressurized and fed back to the inlet side of the first membrane separation device , merged with the raw material gas, and supplied to the first membrane separation device,
Via the low-pressure exhaust gas supply line, the low-pressure exhaust gas from the pressure swing adsorption device is pressurized and supplied to the inlet side of the second membrane separation device and merged with the primary membrane separation exhaust gas from the second chamber of the first membrane separation device. To the separation device ,
Via the secondary membrane separation processing gas supply line, the secondary membrane separation processing gas from the first chamber of the second membrane separation device is supplied to the inlet side of the pressure swing adsorption device and is supplied from the first chamber of the first membrane separation device. A nitrogen separation method characterized by being combined with a primary membrane separation treatment gas and supplying the gas to a pressure swing adsorption device.
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